RU2007149240A - KORIOLISOV FLOWMETER (OPTIONS), METHOD FOR DETERMINING THE RELATIONSHIP OF STRENGTHS OF TWO BRANCHES OF PROCESSING OF SIGNALS OF KORIOLISOV FLOWMETER AND METHOD FOR DETERMINING FLOW - Google Patents

Abstract

The invention relates to a Coriolis flowmeter which has at least one measuring tube (3), which is caused to oscillate during measurement operation and has a medium flowing through it whose flow is measured, a first and a second sensor (21, 23) for detecting an oscillation of the measuring tube (3) which is dependent on the flow and for generating a first and a second sensor signal (S1, S2) and two separate signal processing branches (37, 39), and to a method for flow measurement, which flowmeter and which method make a high degree of measurement accuracy possible by a reference signal (R) being superimposed on the first or the second sensor signal (S1, S2), an auxiliary signal (H) formed by the superimposition passing through both signal processing branches (37, 39), and a first conditioned reference signal (R1) being filtered out of a first signal (S<SUB>?</SUB>) arising at the output of the first signal processing branch (37), and a second conditioned reference signal (R2) being filtered out of a second signal (S<SUB>?</SUB>) arising at the output of the second signal processing branch (39), and a ratio of the gains (V) of the signal processing branches (37, 39) being determined using the conditioned reference signals (R1, R2).

Claims (12)

1. Coriolis flowmeter containing at least one measuring tube (3), configured to excite oscillations in the measuring mode and flow through it the medium whose flow rate is to be measured, the first (21) and second (23) sensors for recording flow-dependent oscillations of the measuring tube (3) and for generating the first (S1) and second (S2) sensor signals, a reference signal generator (48a, 48b) configured to superimpose a reference signal sensor (R) on the second signal (S2), the first branch (37) of signal processing, execution ennuyu to generate and prepare the first signal (S _Δ), corresponding to the difference between the first signal (S1) of the sensor and the auxiliary signal (H) based on the first signal (S1) of the sensor and the auxiliary signal (H) is formed by superposition of the second signal (S2) a sensor and a reference signal (R), a second signal processing branch (39) configured to create and prepare a second signal (S _Σ ) based on an auxiliary signal (H) or a first sensor signal (S1) and an auxiliary signal (H ), two sets of two filters (FS _Δ , FR1; FS _Σ , FR2), of which the first serves to filter out the prepared first reference signal (R1) from the prepared first signal (S _Δ ) and the corresponding signal difference (S1, S2) of the sensors of the first measuring signal (U _Δ ), and the second - to filter out from the prepared second signal (S _Σ ) of the prepared second reference signal (R2) and the second measuring signal (U _Σ ), means (49) for determining, based on the first (R1) and second (R2) prepared reference signals, the gain ratios of the first (37) and second (39) signal processing branches als and means (51) for determining the flow rate (M) based on the first (U _Δ ) and second (U _Σ ) measuring signals, taking into account the ratio (V) of amplifications. 2. The flow meter according to claim 1, characterized in that the second signal (S _Σ ) is equal to the sum of the first sensor signal (S1) and the auxiliary signal (H) or the phase angle between the first (S1) and second (S2) sensor signals is less than a few tens of billions, and the second signal (S _Σ ) is equal to the auxiliary signal (H). 3. The flow meter according to claim 1, characterized in that the first branch (37) of the signal processing contains a differential amplifier (37) and an analog-to-digital converter (A / D _Δ ), and the second branch (39) of the signal processing contains (47) an adder or an amplifier and analog-to-digital converter (A / D _Σ ). 4. The flow meter according to claim 1, characterized in that the sensors (21, 23) contain one coil (25, 27), the generator of the reference signal (48a, 48b) is connected to the first output (55) of the coil (27) of the second sensor ( 23), and the second terminal (59) of this coil (27) is connected to the input of the second branch (39) of the signal processing. 5. The flow meter according to claim 1, characterized in that between the second terminal (57) of the coil (25) of the first sensor (21) and the input of the first signal processing branch (37) are an impedance converter (31) and a preamplifier (33), and a preliminary the gain of the first sensor signal (S1) is adjusted so that the real part (Re (UΔ)) of the first measuring signal disappears, and between the second output (59) of the coil (27) of the second sensor (23) and the input of the second signal processing branch (39) the impedance converter (31) and the preamplifier (35) are located with a given gain . 6. The flow meter according to claim 1, characterized in that a summing or differential amplifier (61) is included in the second signal processing branch (39), the second sensor signal (82) and the reference signal (R) are applied to its inputs (63, 65) , and at the output of which an auxiliary signal (H) is available. 7. Coriolis flowmeter containing at least one measuring tube (3), configured to excite oscillations in the measuring mode and flow through it the medium whose flow rate is to be measured, the first (21) and second (23) sensors for recording flow-dependent oscillations of the measuring tube (3) and for generating the first (S1) and second (S2) sensor signals, the reference signal generator (48a, 48b) configured to superimpose the reference signal sensor (R) on the first signal (S1), the first branch (37) of the signal processing, execute hydrochloric, with the establishment and training of the first signal (S _Δ), corresponding to the difference between the auxiliary signal (H) and a second signal (S2) of the sensor, based on the auxiliary signal (H) is formed by superposition of a first signal (S1) of the sensor and the reference signal (R), and the second sensor signal (S2), the second signal processing branch (39), configured to create and prepare the second signal (S _Σ ) based on the auxiliary signal (H) or the auxiliary signal (H) and the second signal (S2 ) sensor, two sets of two filters (FS _Δ , FR1; FS _Σ , FR2), of which the first serves to filter out the prepared first reference signal (R1) from the prepared first signal (S _Δ ) and the corresponding signal difference (S1, S2) of the sensors of the first measuring signal (U _Δ ), and the second - to filter out from the prepared second signal (S _Σ ) of the prepared second reference signal (R2) and the second measuring signal (U _Σ ), means (49) for determining the ratio (V) of the amplifications of the first (37) and second (39) signal processing branches based on the first (R1) and second (R2) prepared reference systems channels and means (51) for determining the flow rate (M) based on the first (U _Δ ) and second (U _Σ ) measuring signals, taking into account the gain ratio (V). 8. A method for determining the ratio (V) of amplifications of two separate branches (37, 39) of processing the signals of a Coriolis flowmeter containing the first (21) and second (23) sensors for detecting flow-dependent oscillations of the measuring tube (3) and for generating the first (S1 ) and the second (S2) sensor signals, in which either the reference signal (R) is applied to the second sensor signal (S2), the first signal (S _Δ ) corresponding to the difference between the first signal is created and prepared in the first signal processing branch (37) ( S1) sensor and auxiliary signal (N), arr caused by the superposition of the second sensor signal (S2) and the reference signal (R), in the second signal processing branch (39), a second signal (S _Σ ) corresponding to the sum of the first sensor signal (S1) and the auxiliary signal (H) is created and prepared an auxiliary signal (H), or a reference signal (R) is applied to the first sensor signal (S1), in the first signal processing branch (37) a first signal (S _Δ ) is created and prepared corresponding to the difference between the auxiliary signal (H) formed the overlay of the first signal (S1) of the sensor and Nogo signal (R), and a second signal (S2) of the sensor, a second branch (39) processing signals create and prepare the second signal (S _Σ), the corresponding auxiliary signal sum (N) and second signal (S2) of the sensor or the auxiliary signal ( H), from the first (S _Δ ) and second (S _Σ ) signals, the first (R1) and second (R2) prepared reference signals are filtered and based on the prepared reference signals (R1, R2), the ratio (V) of the branch gains (37, 39) signal processing. 9. The method for determining the flow rate (M) using a Coriolis flowmeter according to one of claims 1 to 8, in which the flow rate (M) is proportional to the ratio of the imaginary part (Im (U _Δ )) of the first measuring signal (U _Δ ) and the magnitude of the second measuring signal (U _Σ ) and is inversely proportional to the ratio (V) of amplifications. 10. The method according to claim 9, characterized in that the ratio of amplifications is determined repeatedly, and the flow rate (M) based on the average value of the ratio (V). 11. The method according to claim 9, characterized in that the ratio (V) of the amplifications is determined repeatedly, the distribution of the ratios (V) is determined, and the flow rate (M) based on the average value of the ratios (V) only when the ratios (V) are normally distributed , and the standard deviation of the relations (V) lies below the set value. 12. The method according to claim 9, characterized in that the reference value (V _R ) of the ratio (V) of amplifications is stored in the flow meter, the measured ratio (V) of amplifications is compared with the reference value (V _R ) and, if there is a deviation, they are compensated.